Anjan Kumar Dasgupta

Improvement of thermostability and activity of pectate lyase in the presence of hydroxyapatite nanoparticles

The activity and half-life of pectate lyase (PL) from Bacillus megaterium were nine- and 60-fold, respectively, higher at 90 °C in the presence of hydroxyapatite nanoparticles (NP-PLs) than in the presence of 1mM CaCl(2). Thermodynamic analysis of the nanoparticle-induced stability revealed an enhanced entropy-enthalpy compensation by the NP-PLs since a reciprocal linearity of the enthalpy-entropy change to 90 °C was observed. Without nanoparticles, the linearity range was 70 °C. Such compensation reflected the maintenance of the native structure of proteins. The remarkable enhancement of activity and stability of the NP-PL system at high temperatures may be utilized commercially e.g. in the food industry or the processing of natural fibers that may require a thermotolerant enzyme.

Thermostability, pH stability and dye degrading activity of a bacterial laccase are enhanced in the presence of Cu2O nanoparticles.

The present study relates to a nanotechnology enabled method in which purified laccase from Escherichia coli AKL2 was supplemented with 100 μM copper oxide nanoparticles (Cu(2)O) (NP-laccase). The activity, half life and stability of NP-laccase were enhanced by 4, 42 and 36-fold respectively at high temperature (80 °C) and also over a wide range of pH (4-12) than laccase (in the presence of 0.18 mM CuSO(4)). Thermodynamic analysis of the nanoparticle-induced enzyme stability revealed an enhanced entropy-enthalpy compensation at 80 °C, which reflected the maintenance of its native structure. This was further supported by CD studies. The enhanced activity and thermostability of NP-laccase can be utilized for efficient decolorisation of dyes (both phenolic and azo).

Anti-glycation activity of gold nanoparticles.

Anti-glycation activity of gold nanoparticles (GNPs) has been reported for the first time. Nonenzymatic glycation of alpha-crystallin leads to formation of cataract, or opaque aggregate of proteins. In this article we report prevention of glycation of alpha-crystallin by conjugation with GNPs. Formation of advanced glycosylic end products is prevented even if a strong glycating agent such as fructose is used. In addition, the nanoconjugation can provide some important information on the structural distribution of this dynamic chaperone protein. Because GNPs are biocompatible, their reported anti-glycation activity may have ophthalmological implications.

Therapeutic efficacy of artemisinin-loaded nanoparticles in experimental visceral leishmaniasis

Visceral leishmaniasis (VL) is a fatal vector-borne parasitic syndrome attributable to the protozoa of the Leishmania donovani complex. The available chemotherapeutic options are not ideal due to their potential toxicity, high cost and prolonged treatment schedule. In the present study, we conjectured the use of nano drug delivery systems for plant-derived secondary metabolite; artemisinin as an alternative strategy for the treatment of experimental VL. Artemisinin-loaded poly lactic co-glycolic acid (ALPLGA) nanoparticles prepared were spherical in shape with a particle size of 220.0±15.0 nm, 29.2±2.0% drug loading and 69.0±3.3% encapsulation efficiency. ALPLGA nanoparticles administered at doses of 10 and 20mg/kg body weight showed superior antileishmanial efficacy compared with free artemisinin in BALB/c model of VL. There was a significant reduction in hepatosplenomegaly as well as in parasite load in the liver (85.0±5.4%) and spleen (82.0±2.4%) with ALPLGA nanoparticles treatment at 20mg/kg body weight compared to free artemisinin (70.3±0.6% in liver and 62.7±3.7% in spleen). In addition, ALPLGA nanoparticle treatment restored the defective host immune response in mice with established VL infection. The protection was associated with a Th1-biased immune response as evident from a positive delayed-type hypersensitivity reaction, escalated IgG2a levels, augmented lymphoproliferation and enhancement in proinflammatory cytokines (IFN-γ and IL-2) with significant suppression of Th2 cytokines (IL-10 and IL-4) after in vitro recall, compared to infected control and free artemisinin treatment. In conclusion, our results advocate superior efficacy of ALPLGA nanoparticles over free artemisinin, which was coupled with restoration of suppressed cell-mediated immunity in animal models of VL.

A new approach for the delivery of artemisinin: Formulation, characterization, and ex-vivo antileishmanial studies

HYPOTHESIS Artemisinin, a potential antileishmanial compound with poor bioavailability and stability has limited efficacy in visceral leishmaniasis. Encapsulating artemisinin into poly lactic-co glycolic nanoparticles may improve its effectiveness and reduce toxicity. EXPERIMENTS Artemisinin-loaded nanoparticles were prepared, optimized (using Box-Behnken design) and characterized by dynamic light scattering technique, Atomic force microscopy (AFM), Transmission electron microscopy (TEM) and Fourier Transform-Infra Red spectroscopy. Release kinetics of artemisinin from optimized nanoformulation was studied by dialysis method at pH 7.4 and 5.5. Cytotoxicity and antileishmanial activity of these nanoparticles was tested on murine macrophages by MTT assay and macrophage-infested Leishmania donovani amastigotes ex vivo, respectively. FINDINGS Artemisinin-loaded nanoparticles were 221±14nm in diameter, with polydispersity index, zeta potential, drug loading and entrapment efficiency of 0.1±0.015, -9.07±0.69mV, 28.03±1.14 and 68.48±1.97, respectively. AFM and TEM studies indicated that the particles were spherical in shape. These colloidal particles showed a sustained release pattern in vitro. Treatment with artemisinin-loaded nanoparticles significantly reduced the number of amastigotes per macrophage and percent infected macrophages ex vivo compared to free artemisinin. These nanoparticles were also non-toxic to macrophages compared to artemisinin alone.

Controllable self-assembly from fibrinogen–gold (fibrinogen–Au) and thrombin–silver (thrombin–Ag) nanoparticle interaction

Fibrinogen conjugated gold nanoparticles (fibrinogen–Au) and thrombin conjugated silver nanoparticles (thrombin–Ag) were synthesized by heating (90 °C) the proteins (50 μg protein/ml) with 1 mM AgNO3 or AuCl3. The resultant particles were harvested and examined by flow cytometry, scanning electron microscopy (SEM), transmission emission microscopy (TEM), optical microscopy and dynamic light scattering. SEM and TEM images revealed that the fibrinogen–Au and thrombin–Ag particles interacted. The emergent bio‐nanoconjugate population could be controlled by addition of thrombin–Ag. The method may be exploited in parametrizing coagulation factors and other clinically important protein–protein interactions.

Influence of gold nanoparticle tagged snake venom protein toxin NKCT1 on Ehrlich ascites carcinoma (EAC) and EAC induced solid tumor bearing male albino mice.

Earlier the conjugation of gold nanoparticle (GNP) and snake venom protein toxin NKCT1 was reported and primary characterization was performed. In the present communication, further characterizations of GNP-NKCT1 were done with SEM, EDS, XRD and Raman spectra for its physio-chemical nature and bonding. SEM showed the formation of gold nanoparticles, whereas EDS and XRD confirmed 60-90% gold nanoparticles in the solution. Raman shift corresponding to (C=O), (N-H), (C-N) confirmed the proper conjugation of GNP with NKCT1. GNP-NKCT1 showed anticancer effect both in vivo and in vitro in EAC cell and antitumor effect in EAC induced mice. In in vivo studies, GNPNKCT1 increased MST 108.30% and decreased viable EAC cell count 51.39%. Fluorescent micrograph showed signs of apoptosis (membrane blebbing, membrane disruption). Decreased level of IL-10 and low incorporation of BrdU showed decreased proliferation of EAC induced by GNP-NKCT1. With upregulation of Bax, down regulation of Bcl2 and increased expression of caspase 3/9, it was confirmed that GNP-NKCT1 induced caspase dependent apoptosis pathway in EAC cell. In in vitro studies, GNP-NKCT1 increased the late apoptotic stage of cell and arrested cell cycle division at G0/G1 state. GNP-NKCT1 also decreased the tumor volume and tumor weight in EAC induced tumor in male albino mice. It inhibited angiogenesis, which was confirmed by lower percentage of expression of VEGF. This study indicated the capability of gold nanoparticles which enhanced the tumor uptake of NKCT1 and also suggested that GNP-NKCT1 might be a good source for anti-carcinoma and anti-tumor agents.

In vivo and in vitro toxicity of nanogold conjugated snake venom protein toxin GNP-NKCT1

Research on nanoparticles has created interest among the biomedical scientists. Nanoparticle conjugation aims to target drug delivery, increase drug efficacy and imaging for better diagnosis. Toxicity profile of the nanoconjugated molecules has not been studied well. In this communication, the toxicity profile of snake venom cytotoxin (NKCT1), an antileukemic protein toxin, was evaluated after its conjugation with gold nanoparticle (GNP-NKCT1). Gold nanoparticle conjugation with NKCT1 was done with NaBH4 reduction method. The conjugated product GNP-NKCT1 was found less toxic than NKCT1 on isolated rat lymphocyte, mice peritoneal macrophage, in culture, which was evident from the MTT/Trypan blue assay. Peritoneal mast cell degranulation was in the order of NKCT1 > GNP-NKCT1. The in vitro cardiotoxicity and neurotoxicity were increased in case of NKCT1 than GNP-NKCT1. On isolated kidney tissue, NKCT1 released significant amount of ALP and γ-GT than GNP-NKCT1. Gold nanoconjugation with NKCT1 also reduced the lethal activity in mice. In vivo acute/sub-chronic toxicity studies in mice showed significant increase in molecular markers due to NKCT1 treatment, which was reduced by gold nanoconjugation. Histopathology study showed decreased toxic effect of NKCT1 in kidney tissue after GNP conjugation. The present study confirmed that GNP conjugation significantly decreased the toxicity profile of NKCT1. Further studies are in progress to establish the molecular mechanism of GNP induced toxicity reduction.

Thrombotic Inception at Nano-Scale

Seeing is believing, but the reverse, namely, disbelieving the unseen may often go against the spirit of scientific exploration. This is particularly true for nano-scale objects interacting almost invisibly with biological cells, tissues or organs. Interestingly many of the biological sub-cellular components (e.g. proteins, DNA)have nano-scale dimension. The apparently innocent (chemically inactive) and tiny particulate matter originating from various natural or artificial sources (e.g., pollutant) have been shown to be toxic at different physiological levels. The famous saying by Jeevaka, the legendary physician of the Jataka tales, that there is no herb in the world that is not a drug, however follows. What is toxic in some context have important therapeutic value elsewhere. Nanoparticles do interfere with the thrombo-static equilibrium. While this shift on one hand is a matter of concern, it may provide us a tool to handle or diagnose diseases in which such equilibrium is shifted. One of the finest models to test this dual aspect of the nano-scale objects is Acute Coronary Syndrome (ACS), a leading cause of death in the global scenario. What is known today regarding the effect of nanoscale objects may really be a tip of iceberg and with the advent of smarter nanoparticles one may think of more versatile use of nanotechnology in the management of ACS.

Synthesis of diallyl disulfide (DADS) induced gold nanoparticles: characterization and study of its biological activity in human leukemic cell-lines

Novel approaches to nanoparticle synthesis using herbal products and their potential application in treatments are now in the limelight of recent cancer research. Diallyl disulfide (DADS), a bioactive component of garlic has been used for centuries as an effective remedy for different ailments including cancer. In the present study, DADS is used to synthesize less toxic, eco-friendly gold nanoparticles having anti-proliferative effects against cancer cells. DADS induced gold nanoparticles (D-GNPs) display a characteristic surface plasmon band near 551 nm which is 22 nm red shifted compared to conventionally prepared gold nanoparticles (GNPs) using tri-sodium citrate. Moreover, the hydrodynamic diameter of D-GNP ranges from 70 to 77 nm and its zeta potential is −24.6 mV. A nearly spherical ultra-structure of D-GNPs was visualized under atomic force microscopy and transmission electron microscopy. FT-IR analysis confirms the association of the sulfur group of DADS with these nanoparticles. D-GNPs show dose dependent cytotoxicity in human leukemic cell-lines U937 and K562. Cellular uptake of D-GNPs in U937 leading to nuclear fragmentation and DNA ladder formation are other insightful findings. This report therefore details the synthesis of stable gold nanoparticles using DADS and reveals D-GNPs to be a highly effective anti-proliferative agent showing apoptosis in human leukemia cell-lines.